Highly reflective roofing system

ABSTRACT

A cool roofing system includes highly reflective calcined kaolin particles having a solar reflectance of 80% to 92%. When applied to a roofing substrate, the highly reflective kaolin particles produce a roofing system having a solar reflectance greater than or equal to 70%.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of and claims priority to and the benefit of U.S. application Ser. No. 15/658,342 filed Jul. 24, 2017, now U.S. Pat. No. 10,145,115 which is a continuation of U.S. application Ser. No. 15/057,724 filed Mar. 1, 2016, now U.S. Pat. No. 9,714,512, which is a continuation of U.S. application Ser. No. 14/506,570 filed Oct. 3, 2014, now U.S. Pat. No. 9,303,407, which is a continuation of U.S. application Ser. No. 12/857,948 filed Aug. 17, 2010, now U.S. Pat. No. 8,865,303, which claims the benefit under 35 U.S.C. § 119 of U.S. Provisional Application No. 61/248,285, filed on Oct. 2, 2009, entitled “Highly Reflective Roofing System,” the contents of all of which are herein incorporated by reference in their entirety.

TECHNICAL FIELD

The present invention relates to cool roofing systems. More particularly, the present invention relates to a cool roofing system including highly reflective particles that can be applied to a substrate to increase the solar reflectance of a roofing system to equal to or greater than 70%.

BACKGROUND

Title 24 of the California Code of Regulations, and similar requirements of other agencies, require the solar reflectance of commercial roofing materials to be a minimum of 70%. Many current roofing materials, such as asphalt and modified bitumen, are black in color and have very low solar reflectance. Most of these black roofing materials use mineral granules on the surface to reduce weathering and add fire resistance. Most current roofing granules for asphalt and other dark colored roofing materials are made from crushed rock such as feldspar, which are coated with a ceramic coating in order to make them white enough to achieve an acceptable solar reflectance. However, despite these efforts, the granules that are commercially available today are not bright enough to increase the solar reflectance of the black materials to meet the 70% standard.

SUMMARY

In some embodiments, the present invention is a cool roofing system which includes at least one asphalt layer and at least one granular layer including a plurality of highly reflective calcined kaolin particles having a reflectance ranging from about 80% to about 92% adhered to the asphalt layer. The cool roofing system has a minimum solar reflectance of 70% and, more particularly, a solar reflectance ranging from about 70% to about 82%.

According to various other embodiments, the present invention is a cool roofing system including a roofing substrate, at least one layer of spray polyurethane foam applied to the roofing substrate such that it has a thickness ranging from about one inch to about three inches, an elastomeric coating layer applied over and adhered to the spray polyurethane foam layer, and a plurality of highly reflective, white calcined kaolin particles having a reflectance ranging from about 80% to about 92% adhered to the elastomeric coating layer. The cool roofing system has minimum solar reflectance of 70% and, more particularly, a solar reflectance ranging from about 70% to about 82%.

While multiple embodiments are disclosed, still other embodiments of the present invention will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative embodiments of the invention. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not restrictive.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view of a cool roofing system according to an embodiment of the present invention.

FIG. 2 is a schematic view of a cool roofing system according to another embodiment of the present invention.

DETAILED DESCRIPTION

Various materials have been investigated that may be used to make a roofing granule or particle that when applied to a roofing substrate might achieve a highly reflective roofing surface. These various materials include white quartz, tabular alumina, ceramic sand, and calcined clay from a variety of sources globally. When applied to a black roofing substrate, none of these materials were found to meet the desired 70% solar reflectance standard. White quartz, for example, lacked the necessary opacity to provide sufficient protection to the roofing substrate from the sun's ultra-violet rays. Tabular alumina was extensively tested for its reflectivity and other properties, but the results were not satisfactory. Calcined clay from a variety of sources was investigated and was found not to produce a high enough solar reflectance when applied to a roofing substrate. Ceramic sand which is made from pieces of white porcelain and ground into particles of the desired size was also tested. Like the other materials that were investigated, ceramic sand, when applied to an asphalt roofing substrate, also failed to meet the 70% solar reflectance standard.

Roofing materials and systems containing reflective particles and processes for making the same are generally shown and described in U.S. Pat. No. 7,291,358 and U.S. Published Application No. 2004/0017938, both of which are incorporated herein by reference in their entirety for all purposes.

A cool roofing system according to the various embodiments of the present invention includes highly reflective calcined kaolin particles producing a roofing system having a minimum solar reflectance of 70%. Calcined kaolin is known and referred to as kaolin chamotte, aluminum silicate, calcined clay, calcined china clay, mullite and calcined flint clay. There are many different sources of calcined kaolin found throughout the world. Most calcined kaolin sourced from a variety of locations is off-white, tan or light grey in color. However, there are a few unique sources in the world where there are deposits of kaolin that produce extremely bright white and highly reflective calcined kaolin. These unique sources are found in China and in Central/Eastern Europe.

The kaolin mined in China and Central/Eastern Europe is calcined at temperatures between 1100° C. and 1600° C. to improve the whiteness and hardness of the kaolin clay material. This unique kaolin clay is ground or crushed into granules having an approximate size ranging from 0.3 mm to 2.4 mm and its solar reflectance determined. The solar reflectance of these unique kaolin clay particles ranges from 80% to 92%. When applied to a black roofing substrate at the rate normally used for roofing materials, the resultant reflectance was between 70% and 82%.

One example of highly reflective calcined kaolin that is suitable for use in the various embodiments of the present invention is Kaolinchamotte AS 45 obtained from Amberger Kaolinwerke located in Hirschau and Schnaittenbach, Germany.

FIG. 1 is a schematic drawing of a cool roofing system 10 according to one embodiment of the present invention. The cool roofing system 10 includes at least one asphalt layer 12 such as a layer of bitumen or modified bitumen. Bitumen or modified bitumen can be composed of one or more asphalt layers 14 and one or more layers of a reinforcing material 16 such as, for example, polyester or fiberglass.

The upper asphalt layer 12 includes at least one granular layer 18 including a plurality of highly reflective calcined kaolin particles 20 adhered to or embedded within a top surface of the asphalt layer 12. According to various embodiments, the highly reflective calcined kaolin particles have a solar reflectance ranging from about 80% to about 92% such that when applied to the reinforced asphalt layer 12 result in a roofing system having a minimum solar reflectance of 70% and, more particularly, a solar reflectance ranging from about 70% to about 82%. The particles 20 are bright white in color and have a size ranging from about 0.3 mm to about 2.4 mm. In one embodiment, the particles 62 are of substantially the same particle size distribution. For example, the particles 62 have a particle size distribution that corresponds to the following:

Grade: (ASTM D451) % Retained Specification U.S. Sieve No. Nominal Opening Minimum Maximum 8 2.36 mm 0.0 0.1 12 1.70 mm 4.0 10.0 16 1.18 mm 30.0 45.0 20 850 μm 25.0 35.0 30 600 μm 15.0 25.0 40 425 μm 2.0 9.0 >40 >425 μm 0.0 2.0 *Typical range

The cool roofing system 10 including the asphalt layer is produced by passing a reinforcement material 16, such as fiberglass or polyester, through hot liquid asphalt, which impregnates and coats the reinforcement material 16. This coated strip is then run under a hopper which dispenses the calcined kaolin particles 20 onto the upper surface of the hot asphalt coated strip to substantially fully cover the surface. This strip is then passed over a roller or drum to flatten the particles 20 and press them into the asphalt included in the reinforced asphalt layer 12. The roofing material can be provided in the form of individual shingles or sheets which can then be applied to any commercial, industrial low or steep slope roofing surface.

FIG. 2 is a schematic drawing of a cool roofing system 50 according to another embodiment of the present invention. The cool roofing system 50 shown in FIG. 2 includes at least one layer of spray polyurethane foam 52 applied to a roofing substrate 54. The roofing substrate 54 can be an exposed roofing surface of a structure or sheets or layers of a roofing material. For example, in one embodiment, the layer of spray polyurethane foam 52 can be applied directly onto a roofing surface of a building. In other embodiments, the spray polyurethane foam layer 52 can be applied to a variety of surfaces including concrete, wood, gravel, asphalt, built-up roofing (BUR), modified bitumen, single ply membranes and the like. In one embodiment, the spray polyurethane foam layer 52 can be applied over another spray polyurethane foam layer. A thickness of the spray polyurethane foam layer typically ranges from about 1 inch to about 3 inches.

Additionally, the cool roofing system 50 depicted in FIG. 2 includes at least one layer of an elastomeric coating 56. The elastomeric coating 56 is applied to the upper surface 58 of the spray polyurethane foam layer 52 within 24 hours to protect the spray polyurethane foam from UV light damage. In one embodiment, the elastomeric coating 56 is applied to the upper surface of the spray polyurethane foam layer 52 such that it substantially coats the entire surface of the spray polyurethane foam layer 52. The elastomeric coating can be formed from a wide variety of elastomeric materials including, but not limited to acrylics, urethanes, and silicones.

The cool roofing system 50 also includes at least one granular layer 60. The granular layer 60 includes a plurality of highly reflective calcined kaolin particles 62, such as those described above, adhered to or embedded within the elastomeric coating layer 56. The particles 62 are white in color and can range in size from about 0.3 mm to about 2.4 mm. In one embodiment, the particles 62 are of substantially the same size. Additionally, the highly reflective calcined kaolin particles have a solar reflectance ranging from about 80% to about 92% that when applied to the reinforced asphalt layer 12 results in a roofing system having a minimum solar reflectance of 70% and, more particularly, ranging from about 70% to about 82%.

In one embodiment, the cool roofing system 50 is produced by applying at least one layer of spray polyurethane foam to a roofing substrate such as a roof surface, and then coating the spray polyurethane foam layer with an elastomeric coating layer. While elastomeric coating layer is still wet, calcined kaolin granules are then applied to the coating.

In some embodiments, the calcined kaolin particles used in the roofing systems, as described above, can include a coating and/or a surface treatment. The calcined kaolin particles can be coated and/or their surfaces treated for any number of reasons including dust control, to enhance and/or increase water repellency and to prevent various kinds of staining.

Various compounds can be used to coat or treat the surface the calcined kaolin particles described above according to the various embodiments of the present invention. These compounds include, but are not limited to the following: silanes, siloxanes, polysiloxanes, organo-siloxanes, silicates, organic silicates, silicone resins, acrylics, urethanes, polyurethanes, glycol ethers and mineral oil. Table 1 provides a list of exemplary commercially available coatings and surface treatments and their general descriptions that can be used to coat or treat the surface of calcined kaolin particles or other roofing particles. Additional, exemplary coatings, surface treatments, and methods of coating and treating particles are shown and described in U.S. Pat. Nos. 7,241,500, 3,479,201, 3,255,031, and 3,208,571, all of which are incorporated herein by reference in their entirety for all purposes.

TABLE 1 Coating/Surface Treatment Description Manufacturer Salt Water Resistant Deionized water, alkylalkoxysilanes, DuPont Sealer* siloxanes, alcohol, ethoxylate Maximum Bullet Deionized water, mixed fluoroalkyl salts, DuPont Proof Sealer* propylene glycol monobutyl ether Heavy Duty Sealer* Deionized water mixed fluoroalkyl salts, DuPont propylene glycol, monobutyl ether Heavy Duty Exterior Aliphatic hydrocarbons, proprietary silicone DuPont Sealer* resin, alkyl alkoxysilane, methanol Impregnator Pro* Aliphatic hydrocarbons, butyl acetate, DuPont fluorinated acrylic copolymer, fragrance Rich Color Enhancer Aliphatic hydrocarbons, proprietary silicone DuPont Pro* resin, alkyl alkoxysilane, methanol, butyl acetate AcryShield ® A130 Proprietary acrylic formulation National Coatings Corporation AcryShield ® A179- Proprietary acrylic formulation National Coatings X628 Corporation QW77 Urethane Henkel Corporation Water-based Polyurethane Minwax Corporation polyurethanes Sitren ® 595 Polydimethylsiloxane emulsion Evonik Corporation Sitren ® 270 Aqueous emulsion based on reactive organo- Evonik Corporation siloxanes SILRES ® BS1011A Water-thinable, solventless emulsion based Wacker Chemie AG on a mixture of silane and siloxane SILRES ® BS3003 Water-thinable, solventless emulsion based Wacker Chemie AG on a mixture of silane and siloxane Tego XP 5000 Emulsion of silicone resins Evonik Goldschmidt Corporation Kynar RC-10, 147 Acrylic copolymer, vinylidine fluoride Arkema Inc. copolymer RHOPLEX ™ EC 100% acrylic polymer The Dow Chemical 2540 Company Sycoat 235 Acrylic copolymer emulsion Saiden Technologies *Marketed under the StoneTech ® Professional brand

To maintain the high solar reflectance of the calcined kaolin particles, the coating and/or surface treatment should be applied to the calcined kaolin particles such that the coating and/or surface treatment does not significantly decrease the reflectance of the calcined kaolin particles. For example, many of the coatings and/or surface treatments are sealants or otherwise clear coatings that do not adversely affect the overall solar reflectance of the calcined kaolin particles. In one embodiment, the calcined kaolin particles are treated with an emulsion of silanes and siloxanes without added solvents. In another embodiment, the calcined kaolin particles are treated with SILRES BS3003.

The surface treatments and/or coatings can be applied to calcined kaolin particles using a variety of methods and processes known to those of skill in the art. For example, in one exemplary embodiment, after the raw material has been crushed and sized according to the preferred screen size and packaged, the particles can be treated by adding the particles to an aqueous solution fully saturating the particles with the treatment and then, immediately drying the particles to drive off excess moisture at a temperature not exceeding 600° F. In another exemplary embodiment, after the raw material has been crushed and sized according to the preferred screen size and packaged, the particles can be post treated by spraying the particles with an aqueous solution and then immediately drying the particles to drive off excess moisture at a temperature not to exceed 600° F. In yet another exemplary embodiment, after the raw material has been crushed and sized according to the preferred screen size, the particles can be treated by spraying the particles with an aqueous solution and then immediately kiln drying the particles to drive off excess moisture at a temperature not to exceed 600° F. after which time they can be packaged. In still yet another embodiment of coating and/or treating the surface of calcined kaolin particles, after the raw material has been crushed and sized according to the preferred screen size, the particles are treated by spraying with an aqueous solution followed by immediately aerating the particles to drive off excess moisture after which time the particles can be packaged. The coatings and/or surface treatments may be applied as delivered (e.g., off the shelf) or from aqueous dilutions. The dilution ratio may range from 1:5 to 1:200. The dilutions may be prepared from demineralized water.

EXAMPLES Example 1

Treated Granule Preparation

The method of sample preparation for laboratory testing was as follows. A small plastic or glass container was placed on a digital scale, and the scale zeroed. Approximately 1 oz. (approximately 29.5 ml or 35 grams) of the treatment solution to be tested was placed into the container. The scale was then re-zeroed. 100 grams of calcined kaolin roofing granules was added to the container. The container was then closed with a lid. The container containing the calcined kaolin roofing granules and the treatment solution was vigorously agitated to ensure complete coverage of the granules by the treatment. Next, the treated granules were removed and evenly spread out on a foil tray. The tray containing the treated granules was placed into an oven preheated to 80° C. and the treated granules were dried overnight. The treated granules were removed from the oven and allowed to cool for several hours. The objective of cooling the treated granules was to ensure that the granules return to an ambient or equalized humidity as they might be found prior to a production run of the product.

A brief description of each of the different granules and treatments appear in Table 2 below.

TABLE 2 Description Manufacturer Granule #1 WA-14 calcined kaolin particle Sedlecky Kaolin having a reflectivity ranging (Bo{hacek over (z)}i{hacek over (c)}any, from 70 to 92%. Czech Republic) Granule #2 WA-11 calcined kaolin particle AKW having a reflectivity ranging (Hirschau, Germany) from 70 to 92%. Treatment #1 SITREN 595 Evonik Industries AG (Essen, Germany) Treatment #2 TEGO XP 5000 Evonik Industries AG (Essen, Germany) Treatment #3 SILRES BS1001A Wacker Chemie AG (Munich, Germany) Treatment #4 SILRES BS3003 Wacker Chemie AG (Munich, Germany)

Example 2

Reflectivity

Reflectivity of each of the treated samples was measured using a D&S Reflectometer, Model SSR-ER Version 6 (Devices and Services Company, Dallas, Tex.). To carry out the measurement using the reflectometer, about 100 g of treated sample was placed onto a sample receiving dish. The sample was smoothed out such that the surface of the sample in the dish was roughly level. The reflectometer was cycled through each measurement cycle 1-2 times for each measurement location. A total of five measurements locations were used. The measurement locations represented the four points on a compass (north, south, cast and west), with the fifth measurement taken at the center of the sample dish. The reflectivity readings at each of the five measurement locations were averaged together to obtain an average reflectivity for each individual treated sample. The average reflectivities of each of the treated samples are presented in Table 3 below.

TABLE 3 Sample Reflectivity Granule #1, Treatment #1 82.3% Granule #1, Treatment #2 82.5% Granule #1, Treatment #3 82.5% Granule #1, Treatment #4 82.4% Granule #1, Untreated 83.9% Granule #2, Treatment #1 82.5% Granule #2, Treatment #2 83.2% Granule #2, Treatment #3 83.4% Granule #2, Treatment #4 83.7% Granule #2, Untreated 83.7%

Example 3

Water Repellency Test

The water repellency is a quality control test frequently used in the roofing granule industry. It is important to have hydrophobic roofing granules because hydrophilic granules may exhibit difficulty in being adhered to an asphalt-based substrate. When roofing granules are applied to an asphalt-based substrate, water may then be sprayed on the hot asphalt to cool the heated substrate. If the roofing granules are hydrophilic, water may be present between the granules and the substrate, thereby hindering granule adherence to the asphalt-based substrate.

Each of the granules used in the water repellency test was treated with a solution according to the method described above such that the weight of the treatment solution to the weight of the granules was 2% by weight. Products treated with SILRES BS3003 were treated using a 0.67% dilution. The 0.67% dilution was prepared by weighing 45 g of deionized water into a container and into the same container, weighing 2.50 g of SILRES BS3003. The mixture was gently swirled to form a diluted emulsion. The diluted SILRES BS3003 was then applied to the granules. A brief description of each of the samples is provided in Table 4 below.

TABLE 4 Coating and/or Sample Treatment Granule a SITREN 595 WA-11 b TEGO XP 5000 WA-11 c SYCOAT 235 WA-11 d SILRES BS 1001A WA-11 e ACRYSHIELD A130 WA-11 f ACRYSHIELD A179- WA-11 X628 g EC 2540 WA-11 h KYNAR R-10 147 WA-11 i SITREN 595 WA-14 j TEGO XP 5000 WA-14 k SILRES BS1001A WA-14 l SILRES BS3003 WA-14 m SILRES BS3003 WA-11

WA-11 is a calcined kaolin granule supplied by AKW of Hirschgau, Germany. The reflectivity of WA-11 ranges from about 80% to 92%. WA-14 is a calcined kaolin particle supplied by Sedlecky Kaolin of Božičany, Czech Republic. The reflectivity of WA-14 ranges from about 80% to 92%.

Water repellency was measured by placing three drops of distilled water from an eye dropper onto a 25 gram pile of treated roofing granules. The drops were placed in a depression that had been made in the center of the pile of granules. The three drops of distilled water formed a bead in the depression. A measurement was taken for the amount of time it takes for the bead to break up and sink down through the granules. Longer times indicate better hydrophobicity. The water repellency test results for each of the treated samples are presented in Table 5 below.

TABLE 5 Time to Water Sample Absorption a >120 min b >120 min c <1 min d >12.0 min e <1 min f <45 min g <10 min h <1 min i >120 min j >120 min k >120 min l >120 min m >120 min

The samples treated with SITREN 595, TEGO XP 5000 and SILRES BS 1001A showed more favorable water repellency test results. The sample treated with SILRES BS3003 produced superior results.

Example 4

4-Day Stain Test

The 4-Day Stain Test is another quality control test frequently used in the roofing granule industry. The 4-Day Stain Test is an accelerated measurement of the tendency of roofing granules to adsorb asphaltic oils in an asphalt-based substrate. Each of the granules used in the 4-Day Stain test was treated with a solution according to the method described above such that the weight of the solution to the weight of the granules was 2% by weight. A brief description of each the different granules, treatments and asphalt types used to create each of the samples used evaluated using the 4-Day Stain Test is provided in Table 6 below.

TABLE 6 Description Manufacturer Granule #1 WA-14 calcined kaolin particle Sedlecky Kaolin having a reflectivity ranging (Bo{hacek over (z)}i{hacek over (c)}any, from about 80 to 92%. Czech Republic) Granule #2 WA-11 calcined kaolin particle AKW having a reflectivity ranging (Hirschau, Germany) from about 80 to 92%. Asphalt #1 Type AC-7 asphalt having low Marathon Petroleum melting point. Company LLC (Findlay OH) Asphalt #2 Type III roofing asphalt. This United Asphalts type of asphalt is typically (Commerce City, CO) used in the “hot mop” built up type of roofing. Treatment #1 SITREN 595 Evonik Industries AG (Essen, Germany) Treatment #2 TEGO XP 5000 Evonik Industries AG (Essen, Germany) Treatment #3 SILRES BS1001A Wacker Chemie AG (Munich, Germany) Treatment #4 SILRES BS3003 Wacker Chemie AG (Munich, Germany)

The treated granules for each sample were embedded in asphalt that had been heated to about 200° C. The embedded treated granules were then placed on a tray in an oven at 85° C. for 96 hours (4 days). The trays were removed from the oven, and the asphalt including the embedded granules was allowed to cool to room temperature. The granules were then evaluated for staining using an 8× magnifier/loupe. The stain values were evaluated on a pass/no pass basis and then ranked according to relative staining. The 4-Day Stain Test results are provided in Table 7 below.

TABLE 7 Sample Description Pass/Fail A1 Granule #1, Treatment #1, Asphalt #1 F A2 Granule #1, Treatment #1, Asphalt #2 P B1 Granule #2, Treatment #1, Asphalt #1 F B2 Granule #2, Treatment #1, Asphalt #2 P C1 Granule #1, Treatment #2, Asphalt #1 F C2 Granule #1, Treatment #2, Asphalt #2 F D1 Granule #2, Treatment #2, Asphalt #1 F D2 Granule #2, Treatment #2, Asphalt #2 P E1 Granule #1, Treatment #3, Asphalt #1 F E2 Granule #1, Treatment #3, Asphalt #2 P F1 Granule #2, Treatment #3, Asphalt #1 F F2 Granule #2, Treatment #3, Asphalt #2 P G1 Granule#1, Untreated, Asphalt #1 F G2 Granule#1, Untreated, Asphalt #2 F H1 Granule#2, Untreated, Asphalt #1 F H2 Granule#2, Untreated, Asphalt #2 F I1 Granule #1, Treatment #4, Asphalt #1 F I2 Granule #1, Treatment #4, Asphalt #2 P JI Granule #2, Treatment #4, Asphalt #1 F J2 Granule #2, Treatment #4, Asphalt #2 P

The samples treated with SITREN 595, SILRES BS1001A and SILRES BS3003 showed the most favorable test results. In particular, the samples treated with SILRES BS3003 showed significantly less staining.

Example 5

Adhesion Test

The pick test is a practical test used in the roofing granule industry to predict the adhesive characteristics of roofing granules toward asphalt.

Preparation (Screening) of Particles

The standard #11 particle distribution is what was used in the following steps.

Preparation of Asphalt

Asphalt is heated to about 200° C. The fluid asphalt in poured into an aluminum tray so that the entire surface is just coated. This requires about 5 grams of asphalt per sample.

Pick Test

The asphalt is reheated on a small hotplate to about 200° C. until the asphalt becomes molten. About 25 grams of granules are broadcast across the entire surface until the entire asphalt surface has been covered. While the asphalt is still warm, the granules are pressed into the asphalt, as they would be in a production environment. Due to the rapid cooling that can take place the samples are placed into an 80° C. oven for 4 days after which time they are allowed to completely cool to room/ambient temperature.

The particles are picked out of the cooled asphalt. Only those particles which were embedded well are examined. A picked particle is examined with an 8× magnifier/loupe to estimate the amount of asphalt that was adhered to it. The granules adhesion was measured on two different elements. The first was whether the adhesion failure was due to an adhesive or cohesive failure of the asphalt. The second element was a ranked judgment of the adhesive strength, Best/Average/Poor. The Best rank required a concerted effort to remove granules. The Average rank would be compared to most current market granulated products granule adhesion. The Poor rank was the evidence of little effort required to dislodge the granule. The results of the pick test are presented in Table 8.

TABLE 8 Adhesive/ 1 = BEST, Sam- Cohesive 2 = AVG, Treatment .67%-2% by weight ple Failure 3 = POOR Granule #1, Treatment #1, Asphalt #1 A1 A 3 Granule #1, Treatment #1, Asphalt #2 A2 C 1, 2 Granule #2, Treatment #1, Asphalt #1 B1 A 3 Granule #2, Treatment #1, Asphalt #2 B2 A/C 2 Granule #1, Treatment #2, Asphalt #1 C1 A/C 2 Granule #1, Treatment #2, Asphalt #2 C2 A/C 1 Granule #2, Treatment #2, Asphalt #1 D1 A 3 Granule #2, Treatment #2, Asphalt #2 D2 C 1 Granule #1, Treatment #3, Asphalt #1 E1 A/C 3 Granule #1, Treatment #3, Asphalt #2 E2 C 1, 2 Granule #2, Treatment #3, Asphalt #1 F1 C 1 Granule #2, Treatment #3, Asphalt #2 F2 A 3 Granule#1, Untreated, Asphalt #1 G1 C 2 Granule#1, Untreated, Asphalt #2 G2 A 3 Granulc#2, Untreated, Asphalt #1 H1 A/C 1, 2 Granule#2, Untreated, Asphalt #2 H2 A/C 3 Granule#1, Treatment #4, Asphalt #1 I1 C 1 Granule#1, Treatment #4, Asphalt #2 I2 C 1 Granule#2, Treatment #4, Asphalt #1 J1 A/C 1 Granule#2, Treatment #4, Asphalt #2 J2 C 1

Various modifications and additions can be made to the exemplary embodiments discussed without departing from the scope of the present invention. For example, while the embodiments described above refer to particular features, the scope of this invention also includes embodiments having different combinations of features and embodiments that do not include all of the above described features. 

What is claimed is:
 1. A cool roofing system comprising: at least one asphalt layer; and at least one granular layer adhered to or embedded in an exposed surface of the at least one asphalt layer, the at least one granular layer being a top-most layer of the cool roofing system and comprising a plurality of calcined kaolin particles, the cool roofing system having a minimum solar reflectance of 70% or greater, wherein the calcined particles have a solar reflectance of about 80% to 92%, and wherein the calcined particles do not have a surface treatment.
 2. The cool roofing system according to claim 1, wherein the cool roofing system has a solar reflectance of about 70% to about 82%.
 3. The cool roofing system according to claim 1, wherein the calcined kaolin particles have a particle size ranging from about 0.3 mm to about 2.4 mm.
 4. A cool roofing system comprising: a roofing substrate; at least one layer of spray polyurethane foam on the roofing substrate; an elastomeric coating layer adhered to the spray polyurethane foam layer; and a granular layer adhered to or embedded in an exposed surface of the elastomeric coating layer, the granular layer being a top-most layer of the cool roofing system and comprising a plurality of calcined kaolin particles, the cool roofing system having a minimum solar reflectance of at least 70%, wherein the calcined kaolin particles do not have a surface treatment.
 5. The cool roofing system according to claim 4, wherein a thickness of the spray polyurethane foam layer ranges from about 1 inch to about 3 inches.
 6. The cool roofing system according to claim 4, wherein the cool roofing system has a solar reflectance of at least 70% to about 84%.
 7. The cool roofing system according to claim 4, wherein the calcined kaolin particles have a particle size ranging from about 0.3 mm to about 2.4 mm.
 8. The cool roofing system according to claim 4, wherein the elastomeric coating layer comprises an acrylic, a urethane, or a silicone.
 9. The cool roofing system of claim 4, wherein the roofing substrate comprises at least two asphalt layers and at least one reinforcing layer between the at least two asphalt layers.
 10. The cool roofing system of claim 9, wherein the granular layer is adhered to or embedded in an exposed surface of a top-most one of the at least two of the asphalt layers. 